Coordination and Spin States in Fe+(C2H2)n Complexes Studied with Selected-Ion Infrared Spectroscopy.

Fe+(acetylene)n ion-molecule complexes are produced in a supersonic molecular beam with pulsed laser vaporization. These ions are mass selected and studied with infrared photodissociation spectroscopy in the C-H stretching region, complemented by computational chemistry calculations. All C-H stretch vibrations are shifted to frequencies lower than the vibrations of isolated acetylene because of the charge transfer that occurs between the metal ion and the molecules. Complexes in the size range of n = 1-4 are found to have structures with individual acetylene molecules bound to the core metal ion via cation-π interactions. The coordination is completed with four ligands in a structure close to a distorted tetrahedron. Larger complexes in the range of n = 5-8 have external acetylene molecules solvating this n = 4 core ion via CH-π bonding to inner-shell ligands. DFT computations predict that quartet spin states are more stable for all complex sizes, but infrared spectra for quartet and doublet spin states are quite similar, precluding definitive determination of the spin states. There is no evidence for any of these complexes having acetylenes coupled into reacted structures. This is consistent with computed thermochemistry, which finds significant activation barriers to such reactions.

Effects of cupric chloride on coagulation in human plasma: role of fibrinogen.

INTRODUCTION: Copper poisoning is associated with severe multiorgan injury and potentially death if chelation therapy is not administered. Of interest, while important gastrointestinal and urinary tract hemorrhage is associated with copper poisoning, very little is known concerning the nature of copper induced coagulopathy. METHODS: Using thrombelastography, we assessed changes in coagulation kinetics in human plasma following exposure to copper concentrations encountered during poisoning. RESULTS: While time to commence coagulation was not compromised, both velocity of thrombus growth and final strength were diminished. This result was duplicated with one concentration of copper in factor XIII deficient plasma. This pattern of coagulation kinetic response was interpreted as copper mediated fibrinogen dysfunction, perhaps via oxidation of key fibrinogen disulfide bridges. Lastly, experiments wherein glutathione was added implicated copper generated radical oxygen species as one of the mechanisms responsible for compromised coagulation kinetics. CONCLUSIONS: While chelation therapy is the key to survival following copper poisoning, perhaps this and future investigations of how copper affects coagulation may provide insight into effective supportive therapy for patients with active bleeding.